Lower anterior resection 90 degree instrument

ABSTRACT

An articulating surgical instrument is disclosed, and includes an end effector and a drive assembly operably coupled with the end effector. The end effector includes a first drive shaft defining a first axis, and a second drive shaft operably engaged with and extending away from the first drive shaft. The second drive shaft is operably coupled with the end effector and defines a second axis, the second axis different from the first axis. The first drive shaft and the second drive shaft are pivotably arranged such that the first drive shaft and the second drive shaft are configured to transition between a first, substantially straight arrangement and a second, substantially perpendicular arrangement.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.13/719,607 filed Dec. 19, 2012, and the disclosure of theabove-identified application is hereby incorporated by reference in itsentirety.

BACKGROUND

1. Technical Field

The present disclosure relates to surgical apparatuses, devices and/orsystems for performing endoscopic surgical procedures and methods of usethereof. More specifically, the present disclosure relates to a driveassembly for use with a surgical instrument and configured to transitionbetween different arrangements to facilitate use during different typesof surgical procedures.

2. Background of Related Art

Various types of surgical instruments used to surgically join tissue areknown in the art, and are commonly used, for example, for closure oftissue or organs in transaction, resection, anastomoses, for occlusionof organs in thoracic and abdominal procedures, and forelectrosurgically fusing or sealing tissue.

One such surgical instrument is a surgical stapling instrument, whichmay include a tool assembly including an anvil assembly, a cartridgeassembly for supporting an array of surgical staples, an approximationmechanism for approximating the cartridge and anvil assemblies, and afiring mechanism for ejecting the surgical staples from the cartridgeassembly.

In minimally invasive surgical procedures, e.g., laparoscopic and/orendoscopic procedures, a procedure is performed through a small incisionor through a narrow cannula inserted through a small entrance wound ornaturally-occurring orifice in a patient. Because of reduced patienttrauma, shortened patient recovery periods and substantial reduction inoverall cost, minimally invasive procedures are preferred overtraditional, open procedures. In some minimally invasive surgicalprocedures, it is desirable to gain access to locations that are spacedaway from the point of incision or naturally-occurring orifice.Accordingly, it would be desirable to provide an articulation mechanismto maintain the tool assembly in an offset position relative to thedrive assembly. Thus, there is a need for improved articulation and/orpivoting mechanisms that allow the surgeon to manipulate the tool memberin a variety of configurations.

SUMMARY

Further details and aspects of exemplary embodiments of the presentinvention are described in more detail below with reference to theappended figures.

An articulating surgical instrument is disclosed, and includes an endeffector and a drive assembly operably coupled with the end effector.The end effector includes a first drive shaft defining a first axis, anda second drive shaft operably engaged with and extending away from thefirst drive shaft. The second drive shaft is operably coupled with theend effector and defines a second axis, the second axis different fromthe first axis. The first drive shaft and the second drive shaft arepivotably arranged such that the first drive shaft and the second driveshaft are configured to transition between a first, substantiallystraight arrangement and a second, substantially perpendiculararrangement. According to one embodiment, the second drive shaft islaterally offset from the first drive shaft. According to anotherembodiment, each of the first and second drive shafts incorporates abevel gear. The bevel gear of the first drive shaft and the bevel gearof the second drive shaft are configured to interengage.

According to another aspect of the present disclosure, the driveassembly incorporates a frictional gear configured to circumferentiallyengage the second drive shaft. According to a further aspect of thepresent disclosure, the first and second drive housings are pivotablyarranged.

According to a further aspect of the present disclosure, the first driveshaft and the second drive shaft are interconnected by, from proximal todistal, a pair of interengaging bevel gears, a drive pin, and africtional gear assembly. The frictional gear assembly may include africtional gear and a frictional pinion. According to another aspect ofthe present disclosure, the drive assembly is configured to transferrotational motion in the first drive shaft to rotational motion in thesecond drive shaft. In yet another aspect of the present disclosure, thefirst drive shaft defines a first longitudinal length, and the seconddrive shaft defines a second, different longitudinal length. The seconddrive shaft may be longer than the first drive shaft. In another aspectof the present disclosure, the end effector is configured for selectiveradial orientation with respect to the first axis.

A method of using an articulating surgical instrument is also disclosed,and includes providing an end effector and providing a drive assemblyoperably coupled with the end effector. The drive assembly includes afirst drive shaft and a second drive shaft pivotably and operablycoupled with the first drive shaft. The second drive shaft extends inparallel relation and laterally offset from the first drive shaft. Themethod further includes pivoting the second drive shaft such that thesecond drive shaft is disposed at an angle other than 180 degrees withrespect to the first drive shaft. In another aspect of the presentdisclosure, the method includes providing a drive assembly includesproviding a bevel gear on each of the first and second drive shafts. Inyet another aspect of the present disclosure, the method includesproviding a drive assembly includes providing a frictional gearcircumferentially engaging the second drive shaft. In another aspect ofthe present disclosure, the method includes actuating the end effectorwhile the second drive shaft is disposed at an angle other than 180degrees with respect to the first drive shaft. In yet another aspect ofthe present disclosure, the method includes disposing the end effectorin a selected radial orientation.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the present disclosure are described herein withreference to the accompanying drawings, wherein:

FIG. 1 is a perspective view of a surgical articulation apparatusincluding a drive assembly and an end effector;

FIG. 2 is a side cross-sectional view of the drive assembly taken alongsection line 2-2 of FIG. 1;

FIG. 3 is a perspective view of the drive assembly without an endeffector;

FIG. 4 is a perspective view of the internal components of the assembleddrive assembly;

FIG. 5 is a rear perspective view of the drive assembly;

FIG. 6 is a rear perspective view illustrating the internal componentsof the drive assembly;

FIG. 7 is a perspective view of portions of the assembled drive assemblyin operation;

FIG. 8 is a side view of portions of the assembled drive assembly inoperation;

FIG. 9 is a parts-separated view of the drive assembly;

FIG. 10 is a parts-separated view of the end effector and a portion ofthe drive assembly;

FIG. 11 is a perspective view of portions of the assembled driveassembly in operation;

FIG. 12 is a perspective view of the surgical articulation apparatuswith the end effector being rotated;

FIG. 13 is a perspective view of the drive assembly in an alternativeconfiguration; and

FIG. 14 is a side view of portions of the drive assembly in analternative configuration.

DETAILED DESCRIPTION OF EMBODIMENTS

Embodiments of the presently disclosed surgical articulation apparatusare described in detail with reference to the drawings, in which likereference numerals designate identical or corresponding elements in eachof the several views. As used herein the term “distal” refers to thatportion of the surgical articulation apparatus, or component thereof,that is farther from the user, while the term “proximal” refers to thatportion of the surgical articulation apparatus, or component thereof,that is closer to the user.

Referring initially to FIG. 1, a surgical articulation apparatus 1000includes a drive assembly 100 operatively connected with an end effector400. The end effector 400 and the drive assembly 100 are configured foractuation and manipulation by manual or powered surgical instrument. Onesuch suitable surgical instrument is disclosed in made to InternationalApplication No. PCT/US2008/077249, published as WO 2009/039506, and U.S.patent application Ser. No. 12/622,827, published as U.S. PatentApplication Publication No. 2011/0121049, the entire disclosures of eachof which being incorporated herein by reference. In embodiments, thedrive assembly 100 and the end effector 400 are separable from eachother such that the drive assembly 100 is configured for selectiveconnection with any one of a plurality of different end effectors. It isenvisioned that an end effector may include curved jaw members tofacilitate performing certain types of surgical procedures, e.g., duringlower anterior resection (“LAR”) or other colo-rectal surgery.

End effector 400 includes a pair of jaw members, which include acartridge assembly 432 and an anvil 434. Cartridge assembly 432 housesone or more fasteners 433 (FIG. 10) that are disposed therewithin and isconfigured to deploy the fasteners 433 upon firing of surgicalarticulation apparatus 1000. The anvil 434 is movably, e.g., pivotably,mounted to the end effector 400 and is movable between an open position,spaced apart from cartridge assembly 432, and a closed position whereinanvil 434 is in close cooperative alignment with cartridge assembly 432,to clamp tissue. End effector 400 is operated via transmission ofmechanical force through drive assembly 100, as will be describedfurther below.

Drive assembly 100, as shown, includes a proximal portion 200 defining alongitudinal axis “A” and a distal portion 300. The proximal and distalportions 200, 300 of drive assembly 100 are pivotably attached, as willbe described further below.

Turning momentarily to FIG. 9, the components of drive assembly 100 areshown in parts-separated view. Proximal portion 200 of drive assembly100, as described above, includes a housing 210. Housing 210 is asubstantially cylindrical piece defining a passage 212 therethrough.Passage 212 may have an irregular configuration, e.g., θ-shaped, asshown, to facilitate insertion of other components of the proximalportion 200 of drive assembly 100 for assembly. A pair of longitudinallyextending slots 214 are defined along diametrically opposed outersurfaces of the housing 210, and are configured to facilitate pivotingof distal portion 300 of drive assembly 100, as will be describedfurther below. A distal portion of housing 210 defines a recess 216 thatis dimensioned to accommodate various components of the drive assembly100, as well as to facilitate relative pivoting of the proximal portion200 and distal portion 300 of the drive assembly 100, as will bedescribed further below.

Proximal portion 200 of drive assembly 100 further includes a driveshaft 220, a collar 230, a mounting brace 240, a cap member 250, a bevelgear 260, and a drive adapter 270. While certain portions of theproximal portion 200 of drive assembly 100 disclosed above will bedescribed as physically located within the distal portion 300 of driveassembly, these portions will be understood to be functionallyassociated with the proximal portion 200 of drive assembly 100, as willbe described further below.

Drive shaft 220, as shown, is a substantially straight, elongate memberthat is disposed coaxially with the longitudinal axis A (FIG. 1). Driveshaft 220 includes a distal portion 222 having a configuration definedby plurality of intersecting flat sides, e.g., a hexagonalconfiguration. The distal portion 222 of drive shaft 220 is configuredto interengage other portions of drive assembly 100, as will bedescribed further below. Accordingly, drive shaft 220 is a substantiallyrigid member that is configured to transmit rotational forcestherealong. In embodiments, drive shaft 220 may be formed of, e.g., ametallic or composite material.

Collar 230 is a substantially straight, tubular member that defines apassage 232 therethrough for receiving a portion of the drive shaft 220,and is dimensioned to align with and abut a portion of the mountingbrace 240, as will be described further below. Collar 230 has asubstantially smooth configuration that is configured to isolate thedrive shaft 220 from the inner wall of the passage 212 of housing 210during operation thereof, as will be described further below.

Mounting brace 240 includes a bridge portion 242 defining an aperture243 therethrough for receiving a portion of the drive shaft 220. Bridgeportion 242 is configured to be perpendicularly oriented relative to thelongitudinal axis A (FIG. 1). A pair of parallel arms 244 extenddistally from opposing sides of the bridge member 240, and each of theparallel arms 244 defines an aperture to receive one of a pair of pegs246, as will be described further below.

Cap member 250, as shown, is a substantially flat member defining acentral aperture 252 for receiving a portion of drive shaft 220, and apair of lateral apertures 254. Cap member 250 is configured to couplethe proximal portion 200 and distal portion 300 of drive assembly 100,as will be described further below.

Bevel gear 260 is a substantially circular member defining an aperture262 therethrough. Aperture 262 includes a flat 263 that is configured toengage a portion of the drive adapter 270, as will be described furtherbelow. A plurality of teeth 264 is circumferentially disposed about adistal portion of the bevel gear 260, and are disposed in obliquerelation with respect to the aperture 262.

Drive adapter 270 is disposed distally of the bevel gear 260, andincludes a coupling portion 272 and a shaft portion 278 separated by aflange 275. Coupling portion 272 has a substantially circularconfiguration and includes a flat 273 formed on an outer surfacethereof. Coupling portion 272 is configured to fit within the aperture262 of bevel gear 260 such that the flat 273 of the coupling portion 272engages the flat 263 within the aperture 262 of the bevel gear 260, aswill be described further below. Coupling portion 272 also defines anaperture 274 therethrough having a substantially hexagonal configurationto engage distal portion 222 of drive shaft 220, as will be describedfurther below. A distal portion of the shaft portion 278 of driveadapter 270 also defines a flat 279 configured to engage a portion ofthe distal portion 300 of drive assembly 100, as will be describedfurther below.

With focus now on the distal portion 300 of drive assembly 100, distalportion 300 includes a bevel gear 320, a drive pin 330, an orientationmechanism 340, a neck 350, a brace 360, a frictional gear assembly 370,a drive shaft 380, and a drive housing 390.

Bevel gear 320 has a substantially similar configuration to bevel gear260 of the proximal portion 200 of drive assembly 100 described above.Accordingly, bevel gear 320 is a substantially circular member definingan aperture 322 therethrough. Aperture 322 includes a flat 323 that isconfigured to engage drive pin 330, as will be described further below.A plurality of teeth 324 is circumferentially disposed about a proximalportion of the bevel gear 320, and are disposed in oblique relation withrespect to aperture 322 of the bevel gear 320. In one orientation of thedrive assembly 100, the aperture 322 is configured to receive a portionof the drive adapter 270 of the proximal portion 100 of the driveassembly 100, as will be described further below.

Drive pin 330, as shown, is a substantially circular, elongate memberthat has a proximal portion 332 and a distal portion 336 separated by acircular flange 335. The proximal portion 332 is dimensioned to fitthrough the aperture 322 defined in the bevel gear 320, and includes aflat 333 configured to engage the flat 323 of the aperture 322. Thedistal portion 336 of the drive pin 330 also includes a flat 337 forengaging the frictional gear assembly 370, as will be described furtherbelow.

Orientation mechanism 340 includes a pair of ratcheting plates 342, eachdefining an aperture 344 therethrough for passage of a portion of thedrive pin 330, and each having a grooved surface 346 formed thereon.Ratcheting plates 342 may be configured as, e.g., face gears.Accordingly, the grooved surface 346 of each of the ratcheting plates342 may be configured as a series of radially-extending ridges thatextend outwardly from the aperture 344. The ratcheting plates 342 arearranged such that the grooved surfaces 346 of each respectiveratcheting plate 342 are opposed and are configured to interengage, aswill be described further below. Orientation mechanism 340 also includesa spring 348 having an aperture 349 therethrough to accommodate aportion of the drive pin 330. Spring 348 is configured to abut thedistal ratcheting plate 342.

Neck 350, as shown, is a substantially cylindrical member that defines achannel 352 therethrough for receiving a portion of the drive pin 330.Neck 350 also defines an aperture 354 (FIG. 5) on a rear surface thereofto accommodate insertion of the drive adapter 270 in one arrangement ofthe surgical articulation apparatus 1000, as will be described furtherbelow. A pair of diametrically opposed slots 356 are formed on an outersurface of the neck 350 for receiving the pegs 246 associated with themounting brace 240 described above. Neck 350 also defines a recess 358on an outer surface thereof for receiving cap member 250. The channel352 of the neck 350 is configured to accommodate various components ofthe distal portion 300 of the drive assembly 100, as will be describedfurther below.

Brace 360 is a substantially cylindrical member defining a channel 362therethrough for receiving a portion of the drive pin 330. Brace 360includes a proximal collar 364 configured to fit within the channel 352of the neck 350, a central portion 364, and a pair of arms 366 extendingfrom the central portion 364. Arms 366 extend from diametrically opposedportions of the central portion 364, and each defines an outer slot 367configured to engage a portion of the drive housing 390, and each arm366 defines a radially inward seat 368 to accommodate a portion of theend effector 400 (FIG. 1), as will be described further below.

Frictional gear assembly 370, as shown, includes a frictional gear 372and a frictional pinion 374. Frictional gear 372 includes an aperture372 a having flat 372 b for engaging the flat 333 of the drive pin 330,as will be described further below. Frictional gear 372 also includes anouter frictional surface 372 c that is configured to frictionally engagea portion of the frictional pinion 374. Accordingly, the frictionalsurface 372 c of frictional gear 372 may be formed of africtionally-enhanced material, e.g., a polymeric material.

Frictional pinion 374 defines an aperture 374 a therethrough forreceiving a portion of the drive shaft 380, and has an outer frictionalsurface 374 b configured to frictionally engage the outer frictionalsurface 372 c of the frictional gear 372. Accordingly, the frictionalsurface 374 b of frictional pinion 374 may also be formed of africtionally-enhanced material, e.g., a polymeric material.

Drive shaft 380 defines a perpendicular axis “B” relative tolongitudinal axis A (FIG. 1) and is configured as an elongate memberhaving a proximal coupling portion 382, a central threaded portion 384,and a distal coupling portion 386. The proximal coupling portion 382 isconfigured to be fixedly disposed, e.g., press or interference fit, intothe aperture 374 a of the frictional pinion 374. Drive shaft 380 mayhave a similar configuration but a different length than drive shaft220, e.g., drive shaft 380 may be longer than drive shaft 220. Driveshaft 380 is configured to transmit rotational forces therealong, aswill be described further below. In embodiments, drive shaft 220 may beformed of, e.g., a metallic or composite material.

Drive housing 390 is an elongate member defining a channel 392 therein.Channel 392 includes a slot 394 that is configured to support the driveshaft 380, as well as a portion of end effector 400, as will bedescribed further below. Drive housing 390 also includes a pair of tabs394 configured to engage the outer slot 368 of the brace 360.

Turning to FIGS. 2-6, the drive assembly 100 is shown assembled and incross-sectional and perspective view, respectively. Referring initiallyto the proximal portion 200 of the drive assembly 100, collar 230 andmounting brace 240 are disposed within the passage 212 of the housing210. The proximal portion 222 of the drive shaft 220 is inserted throughthe passage 232 of the collar 230, and the aperture 243 of the mountingbrace 240. The pegs 246 are inserted through the apertures in theparallel arms 244 and into the slots 356 of the neck 350 (best shown inFIG. 5) to secure the mounting brace 230 in position. Because the collar230 rests proximally upon the bridge portion 242 of the mounting brace240, the collar 230 is maintained within the passage 212 of the housing200. Cap member 250 is seated within the recess 358 of the neck 350, andmay be press-fit into the recess 358 or secured with fasteners (FIG. 9)through the lateral apertures 354 of neck 350. The distal portion 224 ofthe drive shaft 220, as shown, is inserted through the central aperture252 of the cap member 250 to engage the interior surfaces of thecoupling portion 272 of the drive adapter 270. The distal portion 224 ofthe drive shaft 220 may be securely coupled, e.g., press fit, brazed,welded, or the like, with the drive adapter 270 in this manner. Becausethe drive adapter 270 is rests in a perpendicular orientation within thechannel 352 of the neck 350, the drive adapter supports the collar 240,mounting brace 230, and drive shaft 220 within the channel 212 of thehousing 210.

Referring to the distal portion 300 of the drive assembly 100, the drivepin 330 is shown mounted within the channel 352 of the neck 350. Thechannel 352 of neck 350 may be dimensioned such that the drive pin 330is maintained in a substantially stationary position within the channel352. The proximal portion 352 of the drive pin 330 is inserted throughthe aperture 322 of the bevel gear 320, which is thus supported withinthe channel 352 of the neck 350. Bevel gear 320 is arranged on the drivepin 330 such that the teeth 324 of the bevel gear 320 are held inengagement with the teeth 264 (FIG. 2) of the bevel gear 260.

As shown, the proximal collar 364 of the brace 360 is fit within thechannel 352 of the neck 350 such that the brace 360 is supported by theneck 350. Arms 366 of the brace 360 extend from the central portion 364and are engaged with the drive housing 390 via the slot 367 formed oneach arm 366.

Orientation mechanism 340, as shown, is disposed within an internalchamber defined between the neck 350 and the central portion 364 of thebrace 360, with a portion of the drive pin 330 extending throughproximal collar 364 of the brace 360. Because orientation mechanism 340is disposed within an enclosed space, spring 348 biases the ratchetingplates 342 into frictional engagement such that the grooved surfaces 346(FIG. 9) of each ratcheting plate interengage with a predefinedcompressive force “F”.

Frictional gear assembly 370, as shown, is also supported within aninterior portion of the brace 360. Frictional gear 372 receives the flat373 on the proximal portion 372 of the drive pin 330 (FIG. 9).Frictional pinion 374 is disposed in abutting relation distally belowthe frictional gear 372, and receives the proximal coupling portion 382of the drive shaft 380 through aperture 374 a (FIG. 2). In this manner,the frictional gear 372 circumferentially engages the drive shaft 380.Drive shaft 380 extends through the channel 392 (FIG. 2) of the drivehousing 390 such that drive shaft 380 is supported by the brace 360 andthe drive housing 390. In this manner, drive shaft 380 is operablyengaged with and extends away from the drive shaft 220 of the proximalportion 200 of the drive assembly 100. Further, the drive shaft 380 ofthe distal portion 300 of the drive assembly 100 is laterally offsetwith respect to the drive shaft 220 of the proximal portion 200 of thedrive assembly 100.

The operation of drive assembly 100 will now be described. Turning toFIGS. 7 and 8, the internal components of the drive assembly 100 areshown in operation. As the drive shaft 220 is rotated as shown, thedistal portion 222 of the drive shaft 220, engaged with the couplingportion 272 (FIG. 9) of the drive adapter 270, causes the bevel gear260, disposed therearound, to rotate. Because the bevel gear 320 of thedistal portion 300 of the drive assembly 100 is held in operativeengagement with the bevel gear 260 of the proximal portion 100 of thedrive assembly, i.e., the teeth 264, 324 of the respective bevel gears260, 320 interengage, rotation of the bevel gear 260 causes rotation ofthe bevel gear 320. Rotation of the bevel gear 320 causes the drive pin330 to rotate due to the engagement of the flat 333 of the drive pin 330with the flat 323 on the aperture 322 of the bevel gear 320 (FIG. 9). Inthis manner, the interengagement of flat 333 of drive pin 330 and flat323 of the aperture 322 of bevel gear 320 inhibits rotation of the bevelgear 320 relative to the drive pin 330, and ensures that drive pin 330and bevel gear 320 rotate in concert. Rotation of the drive pin 330, inturn, causes rotation of the frictional gear 372. Because the frictionalgear 372 is held in a frictional, abutting, relation with the frictionalpinion 374 (FIG. 2), rotation of the frictional gear 372 causes rotationof the frictional pinion 374. As the drive shaft 380 is fixedly insertedthrough the aperture 374 a of the frictional pinion 374, the drive shaft380 also rotates with the rotation of the frictional pinion 374. In thismanner, rotation of the drive shaft 220 transmits force along aperpendicular path within drive assembly 100 such that rotational motionof the drive shaft 220 of the proximal portion 200 of the drive assembly100 is transferred to rotational motion in the drive shaft 380 of thedistal portion 300 of the drive assembly 100. Accordingly, the endeffector 400 (FIG. 1) may be actuated while the drive shaft 380 isdisposed in a perpendicular relationship with the drive shaft 220.

Turning to FIGS. 10-12, the channel 392 of drive housing 390 supportsthe cartridge assembly 432 which contains the plurality of surgicalfasteners 433 and a plurality of corresponding ejectors or pushers 437.End effector 400 includes an actuation sled 440 having upstanding camwedges 444 configured to exert a fastener driving force on the pushers437, which drive the fasteners 433 from cartridge assembly 432, asdescribed in more detail below. These structures serve to restrictlateral, longitudinal, and elevational movement of the cartridgeassembly 432 within channel 392 of drive housing 390.

A plurality of spaced apart longitudinal slots (not shown) extendthrough cartridge assembly 432 and accommodate the upstanding cam wedges444 of actuation sled 440. The slots communicate with a plurality ofpockets within which the plurality of fasteners 433 and pushers 437 arerespectively supported. The pushers 437 are secured by a pusher retainer(not shown) disposed below the cartridge assembly 432, which supportsand aligns the pushers 437 prior to engagement thereof by the actuationsled 440. During operation, as actuation sled 440 translates throughcartridge assembly 432, the angled leading edges of cam wedges 444sequentially contact pushers 437 causing the pushers to translatevertically within slots 446, urging the fasteners 434 therefrom. Thecartridge assembly 432 also includes a longitudinal slot 485 to allowfor a knife blade 474 to travel therethrough.

With continuing reference to FIGS. 10-12, the end effector 400 includesan anvil cover 435 disposed over the anvil 434. The anvil cover 435protects tissue from moving parts along the exterior of anvil 434. Theanvil cover 435 includes opposed mounting wings 450 and 452 which aredimensioned and configured to engage the anvil 434. The mounting wings450 and 452 function to align the anvil 434 with the cartridge assembly432 during closure.

With confirmed reference to FIGS. 10-12, end effector 400 furtherincludes a drive beam 462 disposed within drive housing 390. The drivebeam 462 includes a vertical support strut 472 and an abutment surface476 which engages the central support wedge 445 of actuation sled 440.The drive beam 462 also includes a cam member 480 disposed on top of thevertical support strut 472. Cam member 480 is dimensioned and configuredto engage and translate with respect to an exterior camming surface 482of anvil 434 to progressively clamp the anvil 434 against body tissueduring firing.

A longitudinal slot 484 extends through the anvil 434 to accommodate thetranslation of the vertical strut 472. This allows the cam member 480 totravel in between the cover 435 and anvil 434 during firing. Inembodiments, the anvil cover 435 may also include a correspondinglongitudinal slot (not shown) formed on an underside thereof and issecured to an upper surface of anvil 434 to form a channel therebetween.

The drive beam 462 includes a distal retention foot 488 a and a proximalretention foot 488 b, each having a bore 489 a and 489 b definedtherethrough. The bores 489 a and 489 b may be either threaded or smoothto provide for travel along the drive screw 460 which passestherethrough. A travel nut 490 having a threaded bore 490 a therethroughis disposed between the distal and proximal retention feet 488 a and 488b. The drive shaft 380 of the distal portion 300 of the drive assembly100 (FIG. 9) is threadably coupled to the travel nut 490 through thebore 490 a, such that as the drive shaft 380 is rotated, the travel nut490 travels in a longitudinal direction along the longitudinal axisdefined by the drive shaft 380 and also engaging the feet 488 a and 488b (not shown).

In use, as the drive screw 460 is rotated in a clock-wise direction, thetravel nut 490 and the drive beam 462 travel in a distal directionclosing the anvil 434 as the cam member 480 pushes down on the cammingsurface 482 thereof. The drive beam 462 also pushes the sled 440 in thedistal direction, which then engages the pushers 437 via the cam wedges444 to eject the fasteners 433. The drive beam 462 may be made of anysuitable first material including, but not limited to, plastics, metals,and combinations thereof. The travel nut 490 may be made of any suitablesecond material also including, but not limited to, plastics, metals,and combinations thereof. The first and second materials may be eithersame or different. In embodiments, the drive beam 462 may include asingle retention foot with a threaded bore defined therethrough, whichis threadably coupled to the drive shaft 380.

Turning to FIGS. 11 and 12, and with additional reference to FIG. 9, theoperation of the orientation mechanism 340 will be described. Asdescribed above, the ratcheting plates 342 are arranged such that therespective grooved surfaces 346 face each other and are compressedtogether by spring 348. The spring 348 exerts a predetermined force onthe distal ratcheting plate 342 such that the interengagement of groovedsurfaces 346 are maintained in a substantially constant radialorientation. However, rotational forces exerted on the ratcheting plates342 in excess of the frictional forces maintained by the spring 348 willcause the distal ratcheting plate 342 to rotate with respect to theproximal ratcheting plate 342. In this manner, the grooved surfaces 346of the distal ratcheting plate 342 will cam, or “ratchet”, over thegrooved surfaces 346 of the proximal ratcheting plate 346. As theorientation mechanism 340 is disposed in a chamber defined between theneck 350 and the brace 360 (shown best in FIG. 2), the brace 360 may berotated relative to the neck 350. In particular, the proximal collar 362of brace 360 rotates within the channel 352 of neck 350. As the endeffector 400 is supported by the brace 360, rotation of the brace 360 inthis manner allows for selective radial orientation of the end effector400 relative to the transverse axis B.

The drive assembly 100 and end effector 400 have been discussed hereinin a perpendicular, i.e., 90 degree, arrangement, with the proximalportion 200 of the drive assembly 100 arranged perpendicularly withrespect to the distal portion 300 of the drive assembly 100 and the endeffector 400 attached thereto. Turning to FIGS. 12 and 13, thetransition of the drive assembly 100 from the 90 degree arrangement(herein, “the second arrangement”) to a first, substantially linear,i.e., 180 degree, arrangement, will be described.

As described above, the drive shaft 220 of the proximal portion 200 ofthe drive assembly 100 is configured to be slidably disposed within thehousing 210 and with respect to the collar 230 and mounting brace 240.The drive shaft 220 may be withdrawn proximally through the passage 212of the housing 210, e.g., by withdrawing the handle portion of anassociated surgical instrument proximally away from the drive assembly100. Accordingly, the distal 222 of the drive shaft is disengaged fromand spaced away from the bevel gear 260 and cap member 250. The distalportion 300 of the drive assembly 100 may then be rotated away from theproximal portion 200 of the drive assembly 100. In particular, the pegs246 extending through the apertures in the arms 244 of the mountingbrace 240 and into the slots 356 of the neck 350 provide pivot pointsabout which the distal portion 300 of the drive assembly 100 rotates.

With the proximal portion 200 and the distal portion 300 of the driveassembly 100 now disposed in the first arrangement, e.g., a 180 degreearrangement, the drive shaft 220 and drive adapter 270 may be inserteddistally through the passage 212 of the housing 210 to directly engagethe bevel gear 320, i.e., the flat 279 on the distal portion of theshaft portion 278 of drive adapter 279 is inserted into the aperture 322(FIG. 2) of the bevel gear 320 such that rotation of the drive shaft 220will cause rotation of the bevel gear 320 and subsequent rotation of thedrive shaft 380 in the manner described above. Transitioning of thedrive assembly 100 between the first arrangement and the secondarrangement occurs in substantially the reverse order, i.e., the driveshaft 220 and drive adapter 270 are disengaged from the bevel gear 320and withdrawn proximally, the distal portion 300 of the drive assembly100 is pivoted to a 90 degree arrangement with respect to the firstportion 200 of the drive assembly 100, and the drive shaft 220 and driveadapter 270 are then inserted through the central aperture 252 in thecap member 250 such that the bevel gear 260 engages the bevel gear 320(see FIG. 4).

It will be understood that various modifications may be made to theembodiments disclosed herein. Therefore, the above description shouldnot be construed as limiting, but merely as exemplifications ofpreferred embodiments. Those skilled in the art will envision othermodifications within the scope and spirit of the claims appendedthereto.

The invention claimed is:
 1. A drive assembly for use with an articulating surgical instrument, the drive assembly comprising: a first bevel gear; a second bevel gear; a first drive shaft coupled to the first bevel gear; and a drive pin coupled to the second bevel gear, a portion of the first drive shaft configured to engage a portion of the second bevel gear; wherein the first drive shaft and the drive pin are configured to transition between a first, substantially linear arrangement where the first bevel gear and the second bevel gear are disengaged from each other, and a second, substantially perpendicular arrangement where the first bevel gear is engaged with the second bevel gear.
 2. The drive assembly according to claim 1, wherein the first drive shaft and the drive pin are pivotally arranged.
 3. The drive assembly according to claim 1, further comprising a second drive shaft laterally offset from the drive pin.
 4. The drive assembly according to claim 3, wherein the first drive shaft and the second drive shaft are interconnected by, from proximal to distal, the first bevel gear, the second bevel gear, the drive pin, and a frictional gear assembly.
 5. The drive assembly according to claim 4, wherein the frictional gear assembly includes a frictional gear and a frictional pinion.
 6. The drive assembly according to claim 3, wherein the first drive shaft defines a first longitudinal length, and the second drive shaft defines a second, different longitudinal length.
 7. The drive assembly according to claim 3, wherein the second drive shaft is longer than the first drive shaft.
 8. The drive assembly according to claim 1, further comprising a frictional gear configured to circumferentially engage the drive pin.
 9. The drive assembly according to claim 1, wherein the first bevel gear is rotatable about a first axis defined by the first drive shaft, and wherein the second bevel gear is rotatable about a second axis defined by the drive pin.
 10. The drive assembly according to claim 1, further comprising a drive adapter configured to engage a portion of the first drive shaft and a portion of the second bevel gear.
 11. The drive assembly according to claim 10, wherein the drive adapter is configured to selectively contact the second bevel gear.
 12. The drive assembly according to claim 11, wherein the drive adapter is configured to selectively contact the second bevel gear when the first drive shaft and the drive pin are in the first, substantially linear arrangement.
 13. The drive assembly according to claim 10, wherein the drive adapter is configured to extend at least partially through an aperture of the second bevel gear.
 14. The drive assembly according to claim 10, wherein the drive adapter is configured to selectively extend at least partially through an aperture of the second bevel gear.
 15. A method of using an articulating surgical instrument, comprising: pivoting a drive pin from a first arrangement where the drive pin and a drive shaft are disposed in a substantially linear arrangement and where a first bevel gear and a second bevel gear are disengaged from each other, to a second arrangement where the drive pin and the drive shaft are disposed in a substantially perpendicular arrangement and where the first bevel gear is in direct engagement with the second bevel gear; and moving a portion of the drive shaft at least partially through an aperture of the second bevel gear.
 16. The method according to claim 15, further comprising actuating an end effector of the articulating surgical instrument while the drive pin is disposed in the second arrangement.
 17. The method according to claim 15, further comprising rotating the first bevel gear about a first axis defined by the first drive shaft, and rotating the second bevel gear about a second axis defined by the drive pin.
 18. The method according to claim 15, wherein moving a portion of the first drive shaft at least partially through an aperture of the second bevel gear is performed while the drive pin and the first drive shaft are in the first arrangement. 